Prediction of the 3D surface topography after ball end milling and its influence on aerodynamics

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Autoren

  • B. Denkena
  • V. Böß
  • D. Nespor
  • P. Gilge
  • S. Hohenstein
  • J. Seume

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Details

OriginalspracheEnglisch
Seiten (von - bis)221-227
Seitenumfang7
FachzeitschriftProcedia CIRP
Jahrgang31
PublikationsstatusVeröffentlicht - 3 Juni 2015
Veranstaltung15th CIRP Conference on Modelling of Machining Operations, CMMO 2015 - Karlsruhe, Deutschland
Dauer: 11 Juni 201512 Juni 2015

Abstract

The surface topography of milled workpieces often defines their performance. One example is blades in turbine engines, where the topography defines the flow losses. This type of complex goods is often machined by ball end mills, either for manufacture or repair. The literature offers various model types to predict the surface topography in order to design a machining process without prior experiment. The most accurate models use the real kinematics of the process and blend the tool with the workpiece. But this type of surface prediction ignores the differences between the reality and the simulation due to vibrations, tool chipping etc. This paper presents a combined approach using the kinematic topography from the machining simulation and adds a stochastic topography based on empirical data. It could be shown, that the usage of the stochastic topography greatly affects the flow losses and thus cannot be ignored.

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Prediction of the 3D surface topography after ball end milling and its influence on aerodynamics. / Denkena, B.; Böß, V.; Nespor, D. et al.
in: Procedia CIRP, Jahrgang 31, 03.06.2015, S. 221-227.

Publikation: Beitrag in FachzeitschriftKonferenzaufsatz in FachzeitschriftForschungPeer-Review

Denkena, B, Böß, V, Nespor, D, Gilge, P, Hohenstein, S & Seume, J 2015, 'Prediction of the 3D surface topography after ball end milling and its influence on aerodynamics', Procedia CIRP, Jg. 31, S. 221-227. https://doi.org/10.1016/j.procir.2015.03.049
Denkena, B., Böß, V., Nespor, D., Gilge, P., Hohenstein, S., & Seume, J. (2015). Prediction of the 3D surface topography after ball end milling and its influence on aerodynamics. Procedia CIRP, 31, 221-227. https://doi.org/10.1016/j.procir.2015.03.049
Denkena B, Böß V, Nespor D, Gilge P, Hohenstein S, Seume J. Prediction of the 3D surface topography after ball end milling and its influence on aerodynamics. Procedia CIRP. 2015 Jun 3;31:221-227. doi: 10.1016/j.procir.2015.03.049
Denkena, B. ; Böß, V. ; Nespor, D. et al. / Prediction of the 3D surface topography after ball end milling and its influence on aerodynamics. in: Procedia CIRP. 2015 ; Jahrgang 31. S. 221-227.
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abstract = "The surface topography of milled workpieces often defines their performance. One example is blades in turbine engines, where the topography defines the flow losses. This type of complex goods is often machined by ball end mills, either for manufacture or repair. The literature offers various model types to predict the surface topography in order to design a machining process without prior experiment. The most accurate models use the real kinematics of the process and blend the tool with the workpiece. But this type of surface prediction ignores the differences between the reality and the simulation due to vibrations, tool chipping etc. This paper presents a combined approach using the kinematic topography from the machining simulation and adds a stochastic topography based on empirical data. It could be shown, that the usage of the stochastic topography greatly affects the flow losses and thus cannot be ignored.",
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AU - Denkena, B.

AU - Böß, V.

AU - Nespor, D.

AU - Gilge, P.

AU - Hohenstein, S.

AU - Seume, J.

N1 - Funding information: The authors thank the German Research Foundation (DFG) for the financial support within the Collaborative Research Center 871: Regeneration of complex capital goods. The authors also appreciate the contribution of Karen Mulleners to this paper.

PY - 2015/6/3

Y1 - 2015/6/3

N2 - The surface topography of milled workpieces often defines their performance. One example is blades in turbine engines, where the topography defines the flow losses. This type of complex goods is often machined by ball end mills, either for manufacture or repair. The literature offers various model types to predict the surface topography in order to design a machining process without prior experiment. The most accurate models use the real kinematics of the process and blend the tool with the workpiece. But this type of surface prediction ignores the differences between the reality and the simulation due to vibrations, tool chipping etc. This paper presents a combined approach using the kinematic topography from the machining simulation and adds a stochastic topography based on empirical data. It could be shown, that the usage of the stochastic topography greatly affects the flow losses and thus cannot be ignored.

AB - The surface topography of milled workpieces often defines their performance. One example is blades in turbine engines, where the topography defines the flow losses. This type of complex goods is often machined by ball end mills, either for manufacture or repair. The literature offers various model types to predict the surface topography in order to design a machining process without prior experiment. The most accurate models use the real kinematics of the process and blend the tool with the workpiece. But this type of surface prediction ignores the differences between the reality and the simulation due to vibrations, tool chipping etc. This paper presents a combined approach using the kinematic topography from the machining simulation and adds a stochastic topography based on empirical data. It could be shown, that the usage of the stochastic topography greatly affects the flow losses and thus cannot be ignored.

KW - Milling

KW - Simulation

KW - Topography

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JO - Procedia CIRP

JF - Procedia CIRP

SN - 2212-8271

T2 - 15th CIRP Conference on Modelling of Machining Operations, CMMO 2015

Y2 - 11 June 2015 through 12 June 2015

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